Stainless Steel in Contact with Other Metallic Materials

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Stainless Steel in Contact
with Other Metallic Materials
Electrolyte
Metal 1
Anode
e-
Metal 2
Cathode
ISBN 978-2-87997-263-3
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Materials and Applications Series, Volume 10
CONTACT WITH OTHER METALLIC MATERIALS
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CONTACT WITH OTHER METALLIC MATERIALS
Table of contents
Stainless Steel in Contact with Other Metallic Materials
Materials and Applications Series, Volume 10
ISBN 978-2-87997-263-3
© Euro Inox 2009
1
2
3
3.1
Introduction
The principles of galvanic corrosion
Relevant factors and examples
Electrolyte resistance
2
3
5
5
3.2 Wetting duration and environments
6
Translated and adapted from ARLT, N. / BURKERT, A /
3.3 The kinetics of electrode reactions
8
ISECKE, B., Edelstahl Rostfrei in Kontakt mit anderen
3.4 Cathode and anode area
8
Werkstoffen (Merkblatt 829), Düsseldorf, Informationsstelle Edelstahl Rostfrei, 4th edition 2005
4
Practical experience in different applications
10
4.1
4.2
4.3
4.4
Water and sewage treatment
Components in atmospheric conditions
Stainless steel in building and construction
Stainless steel in transport applications
Frequently asked questions
Preventing galvanic corrosion
Literature
11
14
15
18
20
22
23
Publisher
Euro Inox
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1030 Brüssel, Belgium
Phone +32 2 706 82 65 Fax +32 2 706 82 69
5
6
Disclaimer
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1
CONTACT WITH OTHER METALLIC MATERIALS
1 Introduction
Complex design requirements can make
it necessary to combine different metallic
materials within the same component. Also,
chance combinations can often be found,
sion potential of the metals in contact; hence
there is usually a corrosion hazard for the
partner material.
The risk of galvanic corrosion occurring
governed only by the availability of, for in-
depends, however, on a multitude of factors.
stance, fasteners or shims. In certain cir-
Besides the materials used, environment
cumstances, such mixed-material designs
and design are crucial. It is therefore diffi-
can lead to corrosion in one of the partner
cult to make a priori judgments about
materials. This phenomenon includes galvanic corrosion1, in which two different
metals form a galvanic couple.
As a result of the formation of galvanic
elements, accelerated corrosion of the less
noble material can occur. The latter may then
suffer a corrosion rate far higher than that to
be expected without any contact with the
the compatibility of materials. The present
publication describes the principles of galvanic corrosion and the main parameters
that allow designers to estimate corrosion
risk.
nobler partner metal. Corrosion-related damage such as unacceptable deterioration of
appearance, leaking tubes or failing fasteners can drastically reduce the service life of
a component and lead to premature replacement. In most technical applications,
stainless steel has the more positive corro-
2
1
Accelerated corrosion of a metal, due to the effect of a corrosion ele-
ment. Other factors include concentration elements, aeration elements
and active/passive elements.
CONTACT WITH OTHER METALLIC MATERIALS
2 The principles of galvanic corrosion
For galvanic corrosion to occur, there
must be:
• different corrosion potentials of
the metals within a given system;
• a conductive connection between the
naturally occur in the metal in isolation; however, the corrosive attack on the anode is
greatly accelerated. In some cases, the formation of galvanic elements can lead to corrosion in materials that would otherwise be
corrosion resistant in the environment in
two metals;
• an electrically conductive humidity
question. This can be the case for passive
film (electrolyte) connecting both
materials such as aluminium, which can be
metals
Figure 1 shows the three prerequisites in
graphic form.
If galvanic corrosion occurs, the less noble material – the anode – is preferentially
attacked whilst the more noble material –
the cathode – is even protected against
corrosion. In fact, the principle of cathodic
locally polarised in a certain environment. In
such cases, localised corrosion phenomena
such as crevice corrosion or pitting corrosion
can be observed, which would not have
occurred without the shift in potential
caused by the formation of galvanic elements.
protection is based on sacrificial anodes
providing protection from corrosion.
The contact of two metals with different
potentials in an electrically conductive solution leads to a flow of electrons from the
anode to the cathode. The electro-chemical
reactions are the same as those that would
Electrolyte
Metal 2
Metal 1
e–
Anode
Cathode
Figure 1
shows the three prerequisites in graphic form.
3
CONTACT WITH OTHER METALLIC MATERIALS
Contrary to widespread belief, the difference of potential in an electrochemical cell
alone is not a good indicator of the actual
risk of galvanic corrosion. It only indicates
Graphite
Alloy 625/ C-276
Superaustenitic stainless steel
Titanium
Alloy 400
Austenitic stainless steel grade 1.4404 (316 L), passive
Nickel
Ni-Al Bronze
90/10 Cupro-Nickel
whether or not such a risk has to be taken
into account. In this context, it should be
remembered that the numerous published
tables of the standard potentials of metals
Al-brass
Copper
Austenitic stainless steel casting
only provide an approximation of differences
of potential. The decisive factor is not the
difference of potential observed under standardised experimental conditions but rather
the actual difference of potential under real
operating conditions. This is why empirical
tables of galvanic series have been produced
for typical environments such as sea water.
Lead
Tin
Carbon steel
Cast steel
Al-2.7 Mg
Zinc
Aluminium
Magnesium
-2000
-1000
-1500
-500
0
500
Potential (mV SCE)
These position the potential of various metals in a given environment (Figure 2).
Awareness of the prerequisites of gal-
Figure 2:
The Galvanic Series in
sea-water at 10 °C [11]
vanic corrosion and a proper understanding
of the examples in Figure 3 make it possible
to determine preventive action, which will be
discussed in section 5.
Figure 3:
Conditions in which
galvanic corrosion
cannot occur
Galvanic corrosion cannot occur …
… without electrically
conductive joints
… in metals with no
difference of potential
Electrolyte
Electrolyte
Metal 1
Metal 2
Metal 1
Metal 2
… without connection by an electrolyte
Metal 1
Insulator
(Metal 1 = Anode, Metal 2 = Cathode)
4
Electrolyte
Electrolyte
Metal 2
Metal 1
Coating
Metal 2
CONTACT WITH OTHER METALLIC MATERIALS
3 Relevant factors and examples
According to Faraday’s law, electro-chemical corrosion processes are directly related
to charge transfer, i.e. the flow of currents.
Currents or current densities are therefore
reduced and the shift of potential at the anode is limited, as illustrated in Figure 4.
Measurement of potential at the surface
identifies, in the case of an insulated anode,
frequently used to measure corrosion. If the
the position of the respective potentials of
conditions for galvanic corrosion are met in
principle, the total corrosion current Itot is
cathode and anode, independently of each
composed of a partial current from selfcorrosion Is (i.e. the part of the corrosion that
is independent of contact with other materials) and a partial cell current Iel (i.e. the part
of the corrosion due to the cell current between the partner materials (Equation 1).
in potential is observed. If an electrically
Itot = Is + Iel
(Equation 1)
other. In the transition area, a marked jump
conductive connection between cathode
and anode exists, a low polarisation of the
anode towards higher values is observed
U
Intensity of element corrosion is determined by the difference of potential between
the two metals (DU), the electrolyte resistance (Rel) and the polarisation resistance at
the anode (Rp,a) and cathode (Rp,c) respectively (Equation 2).
Low resistance
High galvanic corrosion
High resistance
Low galvanic corrosion
Insulated anode
No galvanic corrosion
Cathode
Iel
DU
=
Rel + Rp,a + Rp,c
Anode
Anode
Anode
Cathode
(Equation 2)
From this equation, inferences can be
drawn concerning the factors that determine
galvanic corrosion. These factors are critical
in determining whether or not metallic corrosion will become a technically relevant
problem. The effects of these factors will
therefore be discussed individually.
3.1 Electrolyte resistance
The risk of galvanic corrosion diminishes
with increasing electrolyte resistance. This is
because the reach of the galvanic current is
x
in electrolytes with high resistance (such as
water films resulting from condensation). In
the case of electrolyte films of low resistance
(salt water), a very strong polarisation is
measured. The higher the polarisation, the
higher the corrosion rate of the anode if the
material is active or the higher the probability of reaching critical (corrosion-initiating)
potential if the material is in its passive state.
Table 1 shows specific conductivity values of
various types of water.
Figure 4:
Influence of electrolyte
resistance on anode
polarisation
5
CONTACT WITH OTHER METALLIC MATERIALS
3.2 Wetting duration
and environments
There is a strong interaction between
electrolyte resistance and duration of wetting. This is of critical importance wherever
components are not permanently wetted by
watery liquids. As explained in the description of the prerequisites of galvanic corrosion, the electrolyte film plays a key role.
Without such a film, no galvanic corrosion
can occur. This implies that, in practice, any
combination of metallic materials is uncritical from a corrosion point of view if no electrolyte film is present. This is typical of interiors without condensation. In lighting
fixtures or interior-decoration components,
virtually any material combination can be
used, in normally aerated and heated environments, without restrictions in terms of
corrosion risk (Figure 5).
Both length of exposure and electrolyte
Table 1:
Typical values of specific
conductivity in different
types of water
6
resistance are strongly dependent on local
conditions. In marine, industrial or indoor
swimming pool environments, the probability of galvanic corrosion is significantly higher than in rural atmospheric conditions.
Figure 6 shows the influence of the environment on the corrosion rate of zinc, with and
Environment
Specific conductivity in (V · cm)-1
Pure water
5 · 10-8
Demineralised water
2 · 10-6
Rain water
5 · 10-5
Drinking water
2 · 10-4 - 1 · 10-3
Brackish river water
5 · 10-3
Sea water
3,5 · 10-2 - 5 · 10-2
CONTACT WITH OTHER METALLIC MATERIALS
without contact with stainless steel. It
demonstrates that the proportion of cell
corrosion (i.e. the difference between the
corrosion rates) exceeds that of self-corrosion (i.e. the corrosion rate of zinc without
any contact with the stainless steel) in a
coastal atmosphere and in a sea-water
splash zone.
Besides ambient atmosphere, design
details play a decisive role. Factors that help
humidity films to dry quickly (adequate
aeration, prevention of crevices, free
drainage of rainwater) reduce corrosive
attack. Permanently humid areas in crevices
or covered areas, stagnant water and soiled
surfaces can considerably accelerate galvanic corrosion.
Figure 5:
As electrolytes are typi-
30
cally absent in normally
heated and aerated interior environments, the
Hot-dip galvanised steel
Corrosion rate in µm/a
25
Hot-dip galvanised / stainless steel
Surface ratio anode / cathode = 1:6
combination of stainless
steel with other metallic
20
materials such as painted carbon steel does not
typically involve a risk of
galvanic corrosion in
such circumstances.
15
10
5
0
Urban
atmosphere
Near
steel mill
Coastal
area
Marine
splash zone
Location
Figure 6:
Corrosion rates of
hot-dip galvanized steel,
with and without contact
with stainless steel, in
different environments
7
CONTACT WITH OTHER METALLIC MATERIALS
3.3 The kinetics of
electrode reactions
3.4 Cathode and
anode area
The kinetics of electrode reactions are
expressed in Equation 3 by the polarisation
A factor in the calculation of cell current
density, iel (area-related cell current) is the
ratio of cathodic (Ac) and anodic (Aa) surface
resistance values of the anode and the
cathode. Differences in potential as low as
100 mV can lead to corrosion, while metals
with considerably higher differences of potential can be joined without difficulty. In
fact, difference of potential provides no information about the kinetics of galvanic corrosion. The kinetics of the reaction depend
on the metal. Titanium, for instance, reduces
dissolved oxygen much less readily than
copper. This explains why carbon steel corrodes more quickly in contact with copper
areas. It strongly influences the velocity of
galvanic corrosion (Equation 3).
iel =
Ac
DU
(Equation 3)
·
Aa Rel + Rp,a + Rp,c
As long as the cathodic surface area (the
more noble metal of the galvanic couple) is
very small in comparison to the anodic surface area (the less noble metal) no change in
corrosion behaviour is observed. This situation is shown in Figure 7.
than with titanium, although the latter has
higher positive potential than copper.
In this context, the formation of corrosion
layers also plays a decisive role. These can
significantly change the potential of a mate-
Electrolyte
Metal 1
rial and be an obstacle to the anodic and/or
cathodic partial reaction.
Metal 1
Metal 2
Figure 7:
As the cathode (metal 2)
is small compared to
the anode (metal 1),
no damage is caused.
Stainless steel
Figure 8a, 8b:
Stainless steel fasteners
on much larger galvanized steel components
do not normally cause
corrosion.
8
Galvanized steel
Galvanized steel
Stainless steel
CONTACT WITH OTHER METALLIC MATERIALS
Electrolyte
Metal 2
Metal 2
Figure 9:
Galvanic corrosion
is likely to occur if
the anode (metal 1)
is small and the
cathode (metal 2)
is large
Metal 1
Typical examples can be found when
stainless steel fasteners are used on aluminium or galvanized carbon steel components. Two practical applications are shown
in Figure 8. Even in corrosive conditions, this
material causes virtually no galvanic corrosion.
Under atmospheric conditions, it is
The opposite situation, however, can
cause a problem. If a small anode is surrounded by a large cathode, galvanic corrosion may occur, as shown in Figure 9.
Typical examples of such a situation are
shown in Figure 10. In these cases, it is clear
that, under corrosive conditions, the partner
metal may suffer accelerated corrosion.
sometimes difficult to quantify the active
proportions of anodic and cathodic surfaces.
For a practical evaluation, this may, however, not be necessary. Normally it is sufficient
Figure 11:
To prevent galvanic cor-
to consider the system in general. In material combinations, fasteners should always be
rosion, only stainless
steel fasteners should be
used on stainless steel
panels.
made of the more noble material, so the cathodic surface is small.
Stainless steel
Galvanized steel
Wood
Stainless steel
Figure 10a, 10b:
Practical examples of
the principle shown in
Figure 9 (galvanized
carbon steel in contact
Galvanized steel
with stainless steel, in
a marine atmosphere)
9
CONTACT WITH OTHER METALLIC MATERIALS
4 Practical experience in different applications
Extensive research and practical experience are available concerning the corrosion
behaviour of material combinations involving stainless steel, under different condi-
content, such as 1.4307 or 1.4404. Further
guidance can be found in the relevant literature, provided the corrosion system is considered as a whole.
tions. Some relevant results are shown in
Tables 2 to 5. Most results refer to stabi-
Apart from numerical values, experience
makes it possible to make some general
lized stainless steel grades with higher car-
statements, which will be summarised in the
bon content. In principle, the results are
following sections.
transferable to grades with reduced carbon
Table 2: Corrosion rates of various metallic materials in contact with stainless steel
Galvanic cell
Environment
Area ratio
Corrosion rate
(mm/a)
1.4016
Carbon steel
Zn 99.9
Al 99.9
Cu-DGP
Ti
Drinking water,
aerated
1:1
0.47
0.26
0.17
0.07
< 0.01
1.4541
SF-Cu
Artificial sea water
1:1
1:10
10:1
1:1
1:10
10:1
1:1
1:1
0.12
0.07
1.00
0.38
0.25
1.10
0.61
< 0.01
Carbon steel
Zn
Ti
Table 3: Corrosion rates of ZnCuTi in contact with stainless steel grades 1.4541 and 1.4571 in 0.1 N NaCl (aerated, CO2 saturated,
room temperature) according to DIN 50919
1.4541
1.4571
10
Galvanic cell
Area ratio
Corrosion rate
(mm/a)
ZnCuTi
1:1
1:5
4.39
1.43
ZnCuTi
1:1
1:5
3.88
0.91
CONTACT WITH OTHER METALLIC MATERIALS
Table 4: Corrosion rates of different metallic materials in contact with various stainless steels in an aqueous NaCl solution with 5 %vol. NaCl at
35 °C, surface ratio 1:1 (DIN 50919)
Corrosion rate (mm/a)
Galvanic cell
Carbon steel
Hot-dip galvanized steel
ZnAl 4 Cu 1
AlMg 1
Cu-DGP
CuZn 40
X6CrMo17-1
1.4113
0.62
0.51
0.66
0.15
0.04
0.04
X2CrTi12
1.4512
0.66
0.51
0.66
0.29
0.04
0.04
X5CrNi18-10
1.4301
0.69
0.55
0.69
0.29
0.04
0.04
Table 5: Corrosion rates of different materials in contact with stainless steel grade 1.4439 in the North Sea (field test), duration 1 year
Galvanic cell
Area ratio
Corrosion rate
(mm/a)
1.4439
Carbon steel
1:1
4:1
10:1
0.31
0.75
2.10
1.4439
AlMg 4.5 Mn
1:1
4:1
10:1
0.17
0.26
0.95
1.4439
CuNi 10 Fe
4:1
0.07
1.4439
CuZn 20 Fe
4:1
0.18
4.1 Water and sewage treatment
Depending on its composition, the corrosive effect of water on stainless steel may
vary considerably: deionised water without
impurities is not corrosive (except at extremely high temperatures). Drinking water
and water of similar composition contains
moderate concentrations of chloride ions
(max. 250 mg/L, according to the Drinking
Water Directive). In unfavourable circumstances, these can lead to pitting or crevice
corrosion and, under the combined influence of high temperatures and chloride concentration, to stress corrosion cracking. In
most cases, austenitic CrNiMo grades such
as 1.4401, 1.4404 and 1.4571 are corrosion
resistant, if properly fabricated. There are also numerous cases of the successful use of
grade 1.4301.
In drinking water, the risk of galvanic corrosion is moderate. For many years, combinations of stainless steel, copper, copper
alloys and red brass have been successfully
used both for cold-water and hot-water
applications in tubes, couplers and tanks,
without damage from contact corrosion
(Figure 12). While carbon steel can be combined with stainless steel in low-oxygen
water, coupling galvanised steel and aluminium alloys risks galvanic corrosion in the
latter [2].
11
CONTACT WITH OTHER METALLIC MATERIALS
In sewage systems, conditions are less
obvious. A wide variety of water compositions is observed, some with high conductivity, and the risk of galvanic corrosion is
also increased by the high general corrosiveness of sewage to many materials.
Table 6 gives an overview of the compatibility of various materials in aerated sewage.
In soldered joints, choosing a corrosionresistant solder is critical.
Figure 12:
In plumbing, combinations of stainless steel
with copper and copper
alloys such as gun metal
are successfully used.
Table 6: Compatibility of materials in aerated sewage water
Material with a large area
Material with a small area
Key:
Carbon Steel
Cast iron
Zn
Galvanized steel
Al
Cu
Stainless
steel
Carbon steel / cast iron
+*
+*
–
o/–
+*
Zn / galvanized steel
–
+
–
o*
+*
Al
–
o/–
+*
–
+*
Cu
–
–
–
+*
+*
Stainless steel
–
–
–
o
+
Steel in concrete
–
–
–
+
+
+ good
o uncertain
– poor
* Although combining these partner metals only has a negligible influence on the materials, this combination is not recommended because of the high self-corrosion rate of the less noble partner metal.
12
CONTACT WITH OTHER METALLIC MATERIALS
alloyed grades such as EN 1.4462, 1.4439,
1.4539, or 1.4565, or nickel based alloys.
Recommendations for preventing the corrosion of various metallic materials in water
can be taken from EN 12502, parts 1 to 5 [2].
The risk of galvanic corrosion essentially depends on the conductivity of the water (see
section 2). Deionised water is normally uncritical in this respect.
As a highly conductive environment, seawater tends to encourage galvanic corrosion.
Not only are parts made of aluminium alloys,
2,5
Corrosion rate in g/m2h
Sea-water (with typical chloride ion concentrations of about 16,000 mg/L) and similar high-chloride types of water cause high
corrosive stress and normally require higher
1,000 mm
150 mm
0.2 mm
2
1,5
1
0,5
0
0
2
4
6
8
10
12
Cathode/anode area ratio
Figure 13:
The influence of surface
ratio and distance between anode and cathode
on the corrosion rate of
zinc or galvanized carbon steel at risk, but
also those made of copper or gun metal.
Figure 13 demonstrates the influence of
cathode/anode ratios on corrosion rates in
material combinations involving stainless
steel and carbon steel. It is clear that in
rosion in ferritic and non-molybdenumcontaining austenitic grades, even at low
this highly conductive environment the distance between cathode and anode has no
significant influence. Metallic parts can be
prone to contact corrosion even if they are
relatively distant from each other, provided
an electrically conductive connection exists
(for instance, via a common earth).
There is a general corrosion risk in waterpreparation applications that bring stainless
steel into contact with activated carbon,
which is commonly used in filtration. In some
cases, particles of the filter material can
come loose and get into contact with the
stainless steel. The large surface area of the
filter material can then work as a cathode
and shift the polarisation of the stainless
steel 200 to 300 mV in the positive direction.
This shift can induce crevice and pitting cor-
chloride levels. An example of this process is
shown in Figure 14. Here, corrosion damage
occurred in certain feed water basins of a water works, with an average chloride content
of 150 mg/L, specifically affecting the stainless steel fasteners that join the filter-jet
base plates to the reinforced concrete. Pitting and crevice corrosion were only observed in those filter pools in which activated carbon was used as a filter material and
could come into contact with the fasteners
during rinsing operations. As well as the
specified 1.4301, 1.4571 and 1.4401
grades being used for the various elements
of the fasteners, ferritic stainless steel grade
1.4016 was used by mistake. Not surprisingly, this grade was the most strongly affected by corrosion damage.
carbon steel in contact
with stainless steel in
sea water (permanent
immersion in North Sea
water)
13
CONTACT WITH OTHER METALLIC MATERIALS
Figure 14:
Galvanic corrosion in the
stainless steel fasteners
of a filter basin at a water
treatment installation,
involving activated carbon: assembly (left) and
disassembled anchor
screw of 1.4016 stainless steel, showing loss
of cross section area
from corrosion (right)
4.2 Components in atmospheric
conditions
14
While an electrolyte is typically present at
all times in ducts and containers for aqueous
Because of the limited reach of the elements in ambient air, covering the stainless
steel in the narrow zone along the contact
line is usually sufficient to prevent galvanic
corrosion.
media, this is not necessarily the case for
Permanently wet crevices between stain-
components in ambient air. In such circum-
less steel and a less noble material, such as
stances, corrosion can only occur during ex-
aluminium or zinc or zinc-coated compo-
posure to humidity. The surface may not nec-
nents, can be problem areas. Elastic joint
essarily come into direct contact with rain or
splash water. Often, microscopic humidity
seals, which fill the crevice, are a proven remedy. Sealants, prone to embrittlement and
films may form through absorption of water
vapour from ambient air. Also, visible condensation may occur. Dirt and hygroscopic
deposits on components can have a significant influence on the duration of humidity.
Poorly aerated crevices, for instance under
washers or between overlapping sheets, can
lead to the virtually permanent presence of
humidity. In contrast to corrosion elements
in aqueous systems, the formation of elements here may only concern a very limited
area. The two materials only influence each
other within a very small zone along the contact line, without the larger surface of the
partner metal playing a significant role. In
these cases, surface ratio only has a limited
effect, so the well known surface ratio rules
do not apply in the normal way.
cracking within the crevice can, however,
make the situation worse.
Table 7 provides information on the compatibility of various materials under atmospheric conditions.
CONTACT WITH OTHER METALLIC MATERIALS
4.3 Stainless steel in building
and construction
The use of stainless steel in building and
and condensation, the duration of wetting is
the key factor. Occasional and short-term exposure to humidity films does not normally
lead to galvanic corrosion. Hence, design
construction is on the increase. Beyond its
factors are all-important. Factors favouring
architectural design possibilities, the mater-
the rapid drying of humidity films (good aer-
ial’s easy fabrication and high corrosion re-
ation, prevention of crevices, free drainage of
sistance are of paramount importance. Stain-
rainwater, smooth surfaces) reduce corro-
less steel is used for visible surfaces,
structural components and fasteners (such
as screws). The most usual grades are of the
18/8 CrNi and 17/12/2 CrNiMo types – the
latter particularly for high-quality surfaces in
industrial and urban environments or inaccessible structural components such as facade supports. Having to join stainless steel
sion attack. However, permanently damp areas (in crevices or sheltered areas), stagnant
water and dirt can greatly increase the risk of
galvanic corrosion. Weathered parts from
which dirt is removed by rain and which are
sufficiently aerated to dry quickly are less
to other metallic materials may be difficult to
damp over an extended period and allow dirt
avoid. Corrosion behaviour critically de-
to accumulate.
vulnerable to corrosion than recessed areas,
which, although protected from rain, remain
pends on design factors: on surface areas
Although surface ratios are only of limit-
wetted by rain or condensation, in interior or
ed value in identifying corrosion risk, de-
exterior environments, the interaction of the
metals does not reach far and becomes rele-
signs with small anodes and relatively large
cathodes should generally be avoided. Un-
vant only in the immediate area along the
contact line.
In parts exposed to external atmosphere
less this principle is observed, galvanic corrosion is a possibility, even in well-aerated
areas.
Table 7: The compatibility of materials in ambient air
Material with a large area
Material with a small area
Carbon steel
Cast iron
Zn
Galvanized steel
Al
Cu
Stainless
steel
Carbon steel /
cast iron
+*
–
–
+*
+*
Zn / galvanized steel
+*
+
+
o
+
Al
o/–
o
+
o/–
+
Cu
–
–
–
+
+
Stainless steel
–
–
o/–
+
+
Caption:
+ good
o uncertain
– poor
* Although combining these partner metals only has a negligible influence on the materials, this combination is not recommended because of the high self-corrosion rate of the less noble partner metal.
15
CONTACT WITH OTHER METALLIC MATERIALS
Figure 15:
Fastening of a stainless
steel cover (on a facade
assembly) using galvanized screws: the screws
show white rust and initial discolouration (steel
corrosion) after one year
in urban atmosphere
Galvanized steel
Red rust
steel corrosion
White rust
steel corrosion
Stainless steel
Figure 15 shows an example. The upper
end of horizontal stainless steel sections in
a steel and glass facade was covered using
al combinations. In roof repairs, it is not uncommon to join larger surfaces of stainless
steel with other metals. Such combinations
two galvanized screws. Starting from the
can also be considered uncritical unless the
crevice between the lid and the screw, these
ratio between the stainless steel part and the
show marked white rust formation and even,
aluminium or galvanized part significantly
to some extent, corrosion of the base mate-
exceeds 1:1.
Figures 17 to 20 show practical examples
the
risk of galvanic corrosion in the buildof
rial. These phenomena were observed after
only about 12 months of service, which indicates that this is not a durable solution.
Stainless steel fasteners should be substituted for the galvanized screws.
In roofing technology – both in new build
and renovation – stainless steel is predominantly used for fasteners which are in contact
with other metallic materials or materials
with metallic coatings. Due to the favourable
ratio of anodic and cathodic surfaces, there
is generally no corrosion risk in such materi-
16
ing envelope being efficiently prevented.
CONTACT WITH OTHER METALLIC MATERIALS
Figure 17:
Fastening stainless steel
outer panels to a carbon
steel structure on the
Atomium, Brussels
Figure 18:
The stainless steel outer
panel is insulated from
the inner galvanized
steel panel by suitable
joints.
Figure 19:
Fabricating insulated
panels using stainless
steel for the outer shell
and galvanized carbon
steel for the inner shell
Figure 20:
To prevent galvanic
corrosion, the stainless
steel cladding is fastened
to the carbon steel inner
structure in non-humid
areas.
17
CONTACT WITH OTHER METALLIC MATERIALS
4.4 Stainless steel in transport
applications
In passenger cars and other road vehicles, stainless steel (ferritic grades with a
12 % to 18 % chromium content and austenitic grades with about 18% chromium) is
used for trim, exhaust systems (Figure 21),
fuel tanks (Figure 22) and, increasingly,
body and chassis components. In transport
applications, ferritic grades in combination
with coatings are a common option (Figures
23, 24, 25). There is also a long tradition of
austenitic stainless steels being used in rail
coaches (Figure 26), in many parts of the
world, without problems from galvanic corrosion.
Figure 21:
In automotive exhaust
systems, stainless steel
is the normal choice.
The rubber parts of the
fasteners prevent galvanic corrosion.
18
Figure 22:
Stainless steel is increasingly used for fuel
tanks. The fasteners
keeping them in place
ensure interruption of
electrical conductivity
at the joint.
CONTACT WITH OTHER METALLIC MATERIALS
Figure 23:
Simple insulation techniques make the tram’s
ferritic stainless steel
body compatible with the
carbon steel chassis.
Figure 24:
In this side wall of a commuter train, the structure
and outer panels are in
different grades of stainless steel. As these have
identical potentials, no
galvanic corrosion can
occur.
Figure 25:
Used for buses and
coaches, stainless steel
(usually a painted ferritic
grade) has proved compatible with a carbon
steel chassis.
Here, too, it is essential to avoid crevices
between stainless steel components and
less noble materials, in which corrosive attacks can occur due to dirt and humidity.
Once again, the crevices can be filled with a
suitable polymer. Another effective precaution against galvanic corrosion in transport
applications is the local coating of a contact
zone on the stainless steel side, as described above.
Figure 26:
Rail coaches with outer
panels in austenitic
stainless steel have been
used in many parts of the
world, without galvanic
corrosion problems.
19
CONTACT WITH OTHER METALLIC MATERIALS
Frequently Asked Questions
Question:
Is there a risk of galvanic corrosion if
stainless steel grades of different chemical
composition are joined?
Answer:
Between stainless steels of different
sufficiently corrosion resistant in the conditions concerned (Figure 27).
types (also among different corrosion-resis-
repair of domestic plumbing systems?
Answer:
No problems are to be expected when
stainless steel is combined with copper
plumbing, as both materials have similar corrosion potential in potable water. Plumbing
components made of hot-dip galvanized
steel can also be combined with stainless
steel. However, couplers of copper zinc alloys or red brass are recommended.
tance classes) there is generally no galvanic
Figure 27:
No galvanic corrosion
will occur between different types of stainless
steel, even if they do not
have the same corrosion
resistance.
Question:
Can stainless steel be used in combination with copper or galvanized steel for the
Question:
Can stainless steel rebar be joined with
20
corrosion, as the free corrosion potentials of
both partner metals are identical. However,
carbon steel in reinforced concrete?
Answer:
Yes, for carbon steel reinforcement, such
the corrosion resistance of each alloy must
be considered individually. Also the material with lower corrosion resistance must be
a combination does not normally raise corrosion questions, as the corrosion potentials
are identical. Such a combination can be
CONTACT WITH OTHER METALLIC MATERIALS
used to prevent corrosion, when the reinforcement penetrates the concrete or comes
into contact with tubes. The joint must be
well within the concrete, with a minimum
Stainless steel
Carbon steel
concrete cover of 3 cm. If the carbon steel rebar is in the active state (i.e. it is depassivated, due to the influence of chlorides
and/or carbonation), galvanic corrosion is
recommended, since the areas most at risk
possible. However, in most cases, this effect
is much less significant than that of the
inevitable element formation between active
and passive carbon steel rebar (galvanic
corrosion through an active/passive element), since the cathodic efficiency of stainless steel is much lower than of carbon steel
(Figure 28).
are additionally covered.
Figure 28: Given a minimum coverage of concrete and providing the
carbon steel is in its passive state, stainless steel
reinforcement can be joined with carbon steel
without risk of galvanic
corrosion.
Question:
Can stainless steel infill for parapets be
combined with carbon steel posts?
Answer:
If the design prevents an electrolyte (for
instance rain or melting snow) forming over
an extended period, such a direct contact is
Question:
Are washers made of insulating polymers
acceptable. Otherwise plastic bushes should
be used.
effective for preventing contact corrosion in
mechanical joints?
Answer:
Although this joint does not interrupt
metallic contact between the materials in the
area of the thread, such washers can be
21
CONTACT WITH OTHER METALLIC MATERIALS
5 Preventing galvanic corrosion
The obvious way to prevent galvanic corrosion is to select suitably compatible materials at design stage. If the materials that
have to be used could interfere with each
To reduce the cathodic effect of the stainless steel part, it is often sufficient to coat the
stainless steel around the joint (Figure 29).
The width of the zone to be covered depends
other, protective measures must be taken.
on the conductivity of the corrosive environ-
Section 2 provides guidance on the nature of
these measures. Figure 3 describes the prac-
ment. In components exposed to normal
tical possibilities:
ly conductive electrolyte films, it is often suf-
• Electrical insulation of the components (insulators, plastic bushes or
polyamide washers)
• Positioning of the joint in an area not
exposed to humidity
• Coating a cathode or an anode and
cathode (either on large surface areas
or locally, near the joint).
room atmosphere and rather thin and weakficient to coat an area only a few centimetres
wide along the contact line on the stainless
steel side. In salty liquid films several millimetres thick, the effective cathode area becomes wider than 10 cm.
It should be noted that just coating the
anode is not a suitable way to prevent galvanic corrosion. Imperfection in the coating
or local damage, which are difficult to avoid
on-site, create a critical corrosion element:
any damage to the coating exposes a small
anode, which can then corrode rapidly.
Figure 29:
The prevention of contact
corrosion in galvanized
steel by coating a small
area on the stainless
steel side. Results of an
48-hour salt-spray test:
without a coating, galvanic corrosion induces
rusting (left), while coating stainless steel in the
contact area prevents
galvanic corrosion
(right).
22
Stainless steel
Stainless
steel
Galvanized steel
Coating on the
stainless steel
Galvanized steel
CONTACT WITH OTHER METALLIC MATERIALS
6 Literature
[1] DIN EN ISO 8044,
Ausgabe:1999-11
Korrosion von Metallen und
Legierungen – Grundbegriffe
und Definitionen
[8] W. Schwenk
”Probleme der Kontaktkorrosion“
Metalloberfläche 35
(1981) Nr. 5, S. 158
[2] DIN EN 12502
Teil 1 bis 5, Ausgabe:2005-03
Korrosionsschutz metallischer
Werkstoffe – Hinweise zur
Abschätzung der Korrosionswahrscheinlichkeit in Wasserverteilungsund Speichersystemen
[9] K.-H. Wiedemann, B. Gerodetti, R.
Dietiker, P. Gritsch
”Automatische Ermittlung von
Kontaktkorrosionsdaten und ihre
Auswertung mittels
Polarisationsdiagrammen“
Werkstoffe und Korrosion 29 (1978)
S. 27
[3] H. Gräfen,
”Korrosionsschutz durch
Information und Normung“
Kommentar zum DIN-Taschenbuch
219, Verlag Irene Kuron, Bonn (1988)
S. 37
[10] E. Hargarter, H. Sass
”Kontaktkorrosion zwischen verschiedenen Werkstoffen in Meerwasser“
Jahrbuch der Schiffbautechnischen
Gesellschaft 80
(1986) S. 105
[4] H. Spähn, K. Fäßler
”Kontaktkorrosion“
Werkstoffe und Korrosion 17 (1966)
S. 321
[11] R. Francis
”Galvanic Corrosion:
a Practical Guide for Engineers“
NACE International (2001)
Houston Texas 77084
ISBN 1 57590 110 2
[5] D. Kuron
”Aufstellung von Kontaktkorrosionstabellen für Werkstoffkombinationen
in Wässern“
Werkstoffe und Korrosion 36 (1985)
S. 173
[6] D. Kuron, E.-M. Horn, H. Gräfen
”Praktische elektrochemische
Kontaktkorrosionstabellen von
Konstruktionswerkstoffen des ChemieApparatebaues“
Metalloberfläche 26
(1967) Nr. 2, S. 38
[12] GfKorr-Merkblatt 1.013
”Korrosionsschutzgerechte
Konstruktion”
(2005)
[13] Allgemeine bauaufsichtliche
Zulassung Z-30.3-6
”Erzeugnisse, Verbindungsmittel und
Bauteile aus nichtrostenden Stählen“
(jeweils gültige Fassung)
Sonderdruck 862 der Informationsstelle Edelstahl Rostfrei
[7] H. Spähn, K. Fäßler
”Kontaktkorrosion im
Maschinen- und Apparatebau“
Der Maschinen Schaden 40 (1967)
Nr. 3, S. 81
23
CONTACT WITH OTHER METALLIC MATERIALS
24
Stainless Steel in Contact
with Other Metallic Materials
Electrolyte
Metal 1
Anode
e-
Metal 2
Cathode
ISBN 978-2-87997-263-3
Diamant Building · Bd. A. Reyers 80 · 1030 Brussels· Belgium · Tel. +32 2 706 82-67 · Fax -69 · e-mail info@euro-inox.org · www.euro-inox.org
Materials and Applications Series, Volume 10
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